Touch display

ABSTRACT

A touch display includes a display panel and a touch layer. The display panel has pixel areas, and one of the pixel areas has a pixel pitch in a first direction. The display panel includes a substrate, and a display medium layer disposed over the substrate. The touch layer is disposed over the substrate, and includes slits and an electrode. The slits include a first slit and a second slit adjacent to the first slit. The electrode is disposed between the first slit and the second slit. The electrode includes first linear sections and second linear sections alternately arranged in a second direction.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation application of and claimspriority from U.S. patent application Ser. No. 14/695,701, filed on Apr.24, 2015, which claims the benefit of and claims priority to U.S.Provisional Application No. 61/994,227, filed on May 16, 2014, andTaiwan Patent Application No. 103126148 filed on Jul. 31, 2014, theentireties of which are incorporated by reference herein.

BACKGROUND OF THE INVENTION

Field of the Invention

The present disclosure relates to a display apparatus and in particularto a touch display.

Description of the Related Art

Electronic apparatuses, such as mobile phones or tablet computers, havewildly utilized touch display as inputting interfaces. In general, thetouch display comprises a display panel, and a touch layer and a colorfilter disposed over the display panel. The touch layer comprises aplurality of transparent electrodes arranged in an array and configuredto detect the coordinates of a touch signal on the touch layer. Thecolor filter comprises a plurality of pixels arranged in an array fordisplaying a color image.

The conventional transparent electrodes are overlaid on the pixels. Whenlight beam passes through the color filters and the transparentelectrodes, a moiré pattern may be generated in some images on thescreens of the touch display by a moiré effect due to the arrangement ofthe conventional transparent electrodes and pixels. Therefore, thequality of the image on the touch displays is decreased.

BRIEF SUMMARY OF THE INVENTION

The present disclosure provides a touch display with a reduced moiréeffect. Thus, a moiré pattern on the touch display is decreased.

The present disclosure provides a touch display including a displaypanel and a touch layer. The display panel has pixel areas, and one ofthe pixel areas has a pixel pitch in a first direction. The displaypanel includes a substrate, and a display medium layer disposed over thesubstrate. The touch layer is disposed over the substrate, and includesslits and an electrode. The slits include a first slit and a second slitadjacent to the first slit. The electrode is disposed between the firstslit and the second slit. The electrode includes first linear sectionsand second linear sections alternately arranged in a second direction.The second direction is substantially perpendicular to the firstdirection. One of the first linear sections has an edge, and a firstinflection point and a second inflection point are located at two endsof the edge.

An intersection point is defined as a crossing location of an extensionof the first inflection point in the first direction and an extension ofthe second inflection point in the second direction. A first distance isdefined as a distance between the first inflection point and theintersection point, and a second distance is defined as a distancebetween the second inflection point and the intersection point. A ratioof the second distance to the first distance is in a range from 0.33 to3.05.

The present disclosure provides a touch display including a displaypanel and a touch layer. The display panel has pixel areas, and one ofthe pixel areas has a pixel pitch in the transverse direction. Thedisplay panel includes a substrate, and a display medium layer disposedover the substrate. The touch layer is disposed over the substrate. Thetouch layer includes slits including a first slit and a second slitadjacent to the first slit, and an electrode disposed between the firstslit and the second slit.

A predetermined pitch is defined as a width of the electrode plus awidth of the first slit, a first moiré ratio is defined as (thepredetermined pitch/the pixel pitch)×100%, and the first moiré ratiocomplies with a first formula: 25%+(50%×N)−A%≦the first moirératio≦25%+(50%×N)+A%. The N is 0 or a positive integer, and the A is anadjustment value in a range from 0 to 20.

The conducting-wire portions and the pixel areas are designed accordingto the formula of the present disclosure. The moiré effect of the touchdisplay is decreased, and the moiré pattern of the images on the touchdisplay is decreased.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention can be more fully understood by reading the subsequentdetailed description and examples with references made to theaccompanying drawings, wherein:

FIG. 1 is a schematic view of a touch display in accordance with thepresent disclosure.

FIG. 2 is a schematic view of a display zone of the display panel inaccordance with the present disclosure.

FIG. 3 is a schematic view of a touch layer in accordance with a firstembodiment of the present disclosure.

FIG. 4 is a moiré zone of the touch layer in accordance with a firstembodiment of the present disclosure.

FIG. 5 is a schematic view of a moiré zone of the touch layer inaccordance with a second embodiment of the present disclosure.

FIG. 6 is a schematic view of a touch layer in accordance with a secondembodiment of the present invention.

FIG. 7 is a schematic view of the moiré zone of the touch layer inaccordance with a third embodiment of the present disclosure.

FIG. 8 is a schematic view of a touch apparatus in accordance with thepresent disclosure.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 is a schematic view of a touch display 1 in accordance with thepresent disclosure. The touch display 1 comprises a display panel 10, atouch layer 50, a first polarizing layer (polarizing film) 60, a secondpolarizing layer 70 and a protective layer 80.

The display panel 10 comprises a first substrate 11, a display mediumlayer 12, a color-filter layer 13, a second substrate 14, and athin-film transistor layer 15. The first substrate 11 is made from atransparent material, such as glass. The thin-film transistor layer 15is disposed over the first substrate 11. The display medium layer 12 isdisposed over the thin-film transistor layer 15, or disposed between thefirst substrate 11 and the second substrate 14.

The display medium layer 12 may be a liquid-crystal display layer or anorganic light-emitting display. In the embodiment, the display mediumlayer 12 is a liquid-crystal display layer. The liquid-crystal displaylayer comprises liquid-crystal molecules 121, disposed over thethin-film transistor layer 15. The thin-film transistor layer 15 isconfigured to control the arrangement of the liquid-crystal molecules121 in the display medium layer (liquid-crystal layer) 12. In theembodiment, the liquid-crystal molecules 121 are homogeneous alignmentliquid crystals. In some embodiments, the liquid-crystal molecules 121are vertical alignment liquid crystals or twisted nematic liquidcrystals according the design of the display panel 10.

The color-filter layer 13 is disposed over the display medium layer 12.The color-filter layer 13 is disposed between the display medium layer12 and the second substrate 14, or disposed between the display mediumlayer 12 and the touch layer 50. The color-filter layer 13 is configuredto transform the color of the light beam passing through thecolor-filter layer 13. In another embodiment, the color-filter layer 13is disposed over the first substrate 11.

FIG. 2 is a schematic view of a display zone of the display panel 10 inaccordance with the present disclosure. As shown in FIG. 2, the displayzone comprises a plurality of pixel areas 131. The pixel areas 131 arearranged in an array. Each of the pixel areas 131 comprises a pluralityof sub-pixels 132. The sub-pixels 132 in the pixel area 131 correspondto the color filters with different colors in the color-filter layer 13.The light beam presents different colors after the light beam passesthrough the sub-pixels 132 corresponding to the different color filters.

For example, the pixel area 131 of display panel 10 comprises a redsub-pixel 132 a, a green sub-pixel 132 b, and a blue sub-pixel 132 c.The red sub-pixel 132 a corresponds to red color filter, the greensub-pixel 132 b corresponds to green color filter, and the bluesub-pixel 132 c corresponds to blue color filter. The red sub-pixel 132a, the green sub-pixel 132 b, and the blue sub-pixel 132 c arerepeatedly arranged along the transverse direction D1 in sequence, orarranged by other suitable designs.

When a light beam (ex. white light) emitted by a backlight unit (notshown) passes through the red sub-pixel 132 a, the light beam istransformed to red. When the white light passes through the greensub-pixel 132 b, the white light is transformed to green. When the whitelight passes through the blue sub-pixel 132 c, the white light istransformed to blue. In some embodiments, the pixel area 131 of thedisplay panel 10 comprises a red, a blue, a green, and a whitesub-pixel, or a red, a blue, a green, and a yellow sub-pixel.

The second substrate 14 is made of a transparent material, such asglass. In some embodiments, the second substrate 14 is a transparentflexible substrate. The second substrate 14 is disposed over the displaymedium layer 12. The second substrate 14 is disposed over thecolor-filter layer 13.

The touch layer 50 is configured to generate a touch signal according todetect a touch event. For example, the touch event is triggered by atouch element A1 touching the protective layer 80. In some embodiments,the touch element A1 is a finger or a touch sensing pen. The touch layer50 is disposed over the second substrate 14 and under the protectivelayer 80. The touch layer 50 is also disposed over the first substrate11, or disposed between the first substrate 11 and the second substrate14. In another embodiment, the touch layer 50 is disposed between thecolor-filter layer 13 and the display medium layer 12.

The first polarizing layer 60 is disposed under the first substrate 11,and the second polarizing layer 70 is disposed over the touch layer 50.The first polarizing layer 60 and the second polarizing layer 70 areconfigured to polarize the light beam passing through the firstpolarizing layer 60 and the second polarizing layer 70. In other words,the display medium layer 12, the color-filter layer 13, the secondsubstrate 14, the thin-film transistor layer 15, the touch layer 50, andthe second polarizing layer 70 are disposed between the first substrate11 and the protective layer 80.

The protective layer 80 is made from transparent material, such asglass, to protect the elements inside the touch display 1. In otherembodiments, the second polarizing layer 70 has a function, such as ascratch-proofing function or a dirt-proofing function, since the secondpolarizing layer 70 servers as a protective layer. When a touch elementAl touches the protective layer 80, a touch event is triggered. Thetouch layer 50 detects the touch event and generates a touch signalaccording to the touch event, and thus the location of the touch iscalculated and distinguished.

FIG. 3 is a schematic view of a touch layer 50 in accordance with afirst embodiment of the present disclosure. The touch layer 50 comprisesa plurality of transmission electrodes 51, a plurality of sensingelectrodes 52, a plurality of ground electrodes 53, and a plurality ofslits 54. The transmission electrode 51 comprises a transmission portionTX and a conducting-wire portion W1. The conducting-wire portion W1 isconfigured to connect a signal source (not shown in figures) and thetransmission portion TX.

In the embodiment, the ground electrode 53 is configured to ground thesensing electrodes 52. The electrical potential of the ground electrode53 is about zero. In some embodiments, the ground electrodes 53 areexcluded from the touch layer 50.

In some embodiments, the touch layer 50 further comprises dummyelectrodes (not shown in figures) between the transmission electrodes 51and the sensing electrodes 52 (or the ground electrode 53). The dummyelectrodes are not connected to any electrical potential, and theelectrical potential of the dummy electrodes is floating and not fixed.

The transmission electrode 51, the sensing electrode 52, and the groundelectrode 53 are separated by the slits 54. The slits 54 pass throughthe electrode zones with different electrical potential, such as thetransmission electrodes 51, the sensing electrodes 52, and the groundelectrodes 53. The transmission electrode 51, the sensing electrode 52,the ground electrode 5 or a portion of one of the electrodes is betweentwo adjacent slits 54.

The transmission portion TX and the conducting-wire portion W1 of thetransmission electrode 51, the sensing electrode 52, and the groundelectrode 53 are made from transparent conductive material, such asindium tin oxide (ITO) or indium zinc oxide (IZO). The conducting-wireportion W1 of the transmission electrode 51 is made from a metalmaterial.

A plurality of transmission electrodes 51 extend along a longitudinaldirection D2 and adjacent to the sensing electrode 52. The sensingelectrode 52 and the ground electrode 53 extend along the longitudinaldirection D2. The longitudinal direction D2 is substantiallyperpendicular to the transverse direction D1. The ground electrode 53 isdisposed between two sensing electrodes 52. In another embodiment, theground electrode 53 is excluded from the touch layer 50. The twoadjacent sensing electrodes 52 in FIG. 3 are integrated into one.

The transmission portions TX are substantially arranged along thelongitudinal direction D2, and adjacent to the sensing electrode 52. Theconducting-wire portion W1 is connected to a part of the transmissionportion TX, and extends along the longitudinal direction D2. When thetouch element A1 contacts the protective layer 80 and is disposed overthe transmission portion TX and the sensing electrode 52, thetransmission electrode 51 generates a driving signal.

In some embodiments, the areas of the transmission portions TX are thesame, gradually decreased, or gradually increased along the longitudinaldirection D2. In the embodiment, as shown in FIG. 3, the areas of thetransmission portions TX are gradually decreased along the longitudinaldirection D2. The conducting-wire portions W1 are separated from eachother and arranged along the transverse direction D1.

In the transverse direction D1, the number of conducting-wire portionsW1 is increased from a side of the touch layer 50 to an opposite side ofthe touch layer 50, as shown in FIG. 3. The conducting-wire portions W1and the slits 54 are alternately arranged in a moiré zone Z1, as shownin FIG. 3, for example.

The brightness of the light beam passing through the slits 54 aredifferent from the brightness of the light beam passing through thetransmission electrodes 51, the sensing electrodes 52 and the groundelectrodes 53, since the transmittance of the slits 54 is different formthe transmittance of the transmission electrodes 51, the sensingelectrodes 52 and the ground electrodes 53. Especially, in the moirézone Z1, the conducting-wire portions W1 and the slits 54 are denselyarranged. Alternating bright and shade lines extending along thelongitudinal direction D2 are shown when a light beam passes through themoiré zone Z1.

Moreover, since the pixel areas 131 are arranged in an array, the imageshown in the touch display 1 has a moiré pattern by the moiré effectwhen the touch layer 50 and the color-filter layer 13 are overlapped.When the moiré effect is great, the change of the moiré pattern shown onthe image generated by the touch display 1 is great.

In the embodiment, the conducting-wire portions W1 and the slits 54 arearranged in an appropriate way to decrease the moiré effect. As shown inFIG. 2, the pixel area 131 comprises a pixel pitch P1 in the transversedirection D1. As shown in FIG. 2, in the embodiment, the red, blue andgreen sub-pixels 132 are disposed in the pixel area 131. In anotherembodiment, the red, green, blue and yellow sub-pixels 132 are disposedin the pixel area 131.

FIG. 4 is a moiré zone Z1 of the touch layer 50 in accordance with afirst embodiment of the present disclosure. The conducting-wire portionW1 has a wire pitch P2 in the transverse direction D1. The slit 54 has aslit pitch P3 in the transverse direction D1. The predetermined pitch P4is defined as the wire pitch P2 of the conducting-wire portions W1 plusthe slit pitch P3 of the slit 54. In other words, one of theconducting-wire portions W1 and its adjacent slit 54 have apredetermined pitch P4 in the transverse direction D1. In oneembodiment, the predetermined pitch P4 is defined as a width of one ofthe conducting-wire portions W1 plus a width of its adjacent slit 54.

A moiré ratio is defined as (the predetermined pitch P4/the pixel pitchP1)×100%. The moiré ratio complies with the formula (1) as follows:25%+(50%×N)−A%≦the moiré ratio≦25%+(50%×N)+A%   formula (1)

In the formula (1), N is 0 or a positive integer. In other embodiments,N is in a range from about 0 to 8. A is an adjustment value in a rangefrom about 0 to 20, or 0 to 15. The range of the adjustment value isadjusted according to the tolerance range of the parameters of themanufacturing process.

For example, when both N and A are 0, the moiré ratio is 25%. When thepixel pitch P1 is 100 um, the predetermined pitch P4 is 25 um.Therefore, in the moiré zone Z1, each of the relative overlappingpositions of the pixel areas 131 and the conducting-wire portions W1 maybe different in the transverse direction D1 since the conducting-wireportions W1 in the moiré zone Z1 are designed according to the moirératio in the formula (1). Therefore, the moiré effect is decreased, andthe moiré pattern is decreased or less obvious. Moreover, for example,when N is 1 and A is 0, the moiré ratio is 75%. When N is 1 and A is 1,the moiré ratio is in a range from 74% to 76%.

When the conducting-wire portions W1 are designed and arranged accordingto the range of the moiré ratio mentioned above, the moiré effect of thetouch display 1 is decreased.

As shown in FIG. 4, in the embodiment, the slit 54 is a wave shape. Theslit 54 comprises a plurality of segments 541 and 542. The segments 541and 542 may be linear structures. The segments 541 may be substantiallyparallel to each other, and the segments 542 may be substantiallyparallel to each other. The segments 541 and 542 are alternatelyarranged in substantially a longitudinal direction D2. The segments 541substantially extend along a first extension direction D3, and thesegments 542 substantially extend along a second extension direction D4.

The conducting-wire portion W1 is a conductive layer. The conductivelayer is made from transparent conductive material or metal. Theconducting-wire portion W1 is disposed between two adjacent slits 54,and the conducting-wire portion W1 is wave-shaped structure. The moiréeffect of the touch display 1 is decreased by the wave-shaped slits 54and conducting-wire portions W1.

The conducting-wire portion W1 comprises a plurality of linear sectionsW11 and a plurality of linear sections W12. The linear sections W11 andW12 may be a line structures. The linear sections W11 are substantiallyparallel to each other, and the linear sections W12 are substantiallyparallel to each other. The linear sections W11 and W12 are alternatelyarranged in substantially a longitudinal direction D2. The linearsections W11 substantially extends along the first extension directionD3, and the linear sections W12 substantially extends along the secondextension direction D4. A first acute angle is between the firstextension direction D3 and the longitudinal direction D2. A second acuteangle is between the second extension direction D4 and the longitudinaldirection D2. The first acute angle may be the same as or different fromthe second acute angle.

An inflection point W13 and an inflection point W14 are disposed at twoends of an edge of the linear section W11. The linear section W12 isconnected to the inflection point W13 and the inflection point W14. Theintersection point W15 is disposed at a crossing location of theextension of the inflection point W13 in the transverse direction D1 andthe extension of the inflection point W14 in the longitudinal directionD2. Transverse distance Lx is defined as the distance between theinflection point W13 and the intersection point W15, and longitudinaldistance Ly is defined as the distance between the inflection point W14and the intersection point W15.

The value of the longitudinal distance Ly/transverse distance Lx is in arange from 0.33 to 3.05. In another embodiment, the value of thelongitudinal distance Ly/transverse distance Lx is in a range from 0.4to 2.50, or from 0.45 to 2.15. When the value of longitudinal distanceLy/transverse distance Lx complies with the described range, the moiréeffect that occurs in the moiré zone Z1 is decreased.

An arrangement ratio is defined as (transverse distance Lx/pixel pitchP1)×100% or (longitudinal distance Ly/pixel pitch P1)×100%. The value ofthe arrangement ratio complies with formula (2):25%+(50%×N)−B%≦the arrangement ratio≦25%+(50%×N)+B%   formula (2)

N is 0 or a positive integer. In some embodiments, N is in a range from0 to 8. B is an adjustment value in a range from 0 to 20 or 0 to 15. Therange of the adjustment value, B, may be adjusted according to thetolerance range of the parameters of the manufacturing process. When theconducting-wire portions W1 are designed and arranged in the range ofthe moiré ratio, the moiré effect is decreased.

For example, when N is 1 and the B is 0, the arrangement ratio is about75%. When N is 1 and B is 1, the arrangement ratio is in a range fromabout 74% to 76%. For example, when the pixel pitch P1 is about 100 um,the transverse distance Lx or the longitudinal distance Ly is in a rangefrom about 74 um to 76 um.

FIG. 5 is a schematic view of a moiré zone Z1 of the touch layer 50 inaccordance with a second embodiment of the present disclosure. The moirézone Z1 further comprises a first zone Z11 and a second zone Z12adjacent to the first zone Z11. In some embodiments, the moiré zone Z1comprises at least three zones.

The first zone Z11 and the second zone Z12 are arranged along thetransverse direction D1. The arrangement of the conducting-wire portionsW1 in the first zone Z11 are designed according to the formula (1). Thearrangement of the conducting-wire portions W1 in the second zone Z12are designed according to the formula (3):25%+(50%×(N+1))−A%≦the moiré ratio≦25%+(50%×(N+1))+A%   formula (3)

N in formula (3) is 0 or a positive integer. In some embodiments, N isin a range from 0 to 8. A is an adjustment value. The range of theadjustment value, A, may be adjusted according to the tolerance range ofthe parameters of the manufacturing process. The A is in a range from 0to 20, or 0 to 15. The moiré ratio corresponding to the first zone Z11complies with the formula (1), and the moiré ratio corresponding to thesecond zone Z12 complies with formula (3). Therefore, the predeterminedpitches in the moiré zone Z1 may be different. In the embodiment, thepredetermined pitch P4 of the first zone Z11 is smaller than thepredetermined pitch P5 of the second zone Z12. When the conducting-wireportions W1 in the first zone Z11 and the second zone Z12 are designedaccording to the formula (3), the moiré effect of the moiré zone Z1 isdecreased.

FIG. 6 is a schematic view of a touch layer 50 in accordance with asecond embodiment of the present invention. In the embodiment, aplurality of dummy slits E1 may be disposed in the transmission portionTX, the sensing electrode 52, and the ground electrode 53 to furtherdecrease the moiré effect. One of the electrodes E2 is disposed betweentwo adjacent dummy slits E1.

The dummy slit E1 is a wave-shaped structure extending along thelongitudinal direction D2. In the embodiment, the shape of the dummyslit E1 corresponds to the shape of the slit 54. However, in someembodiments, the shape of the dummy slit E1 may not correspond to theshape of the slit 54. The dummy slits E1 may have different shapesaccording the requirements of the design of the touch display 1. In theembodiment, two ends of the dummy slit E1 are not connected to the slit54 at the same time. In other words, the dummy slit E1 is distributed atone electrode zone having the same electrical potential. In other words,the electrodes around the dummy slit E1 having the same electricalpotential. Some arrangements of the dummy slit E1 may refer to thearrangements of the slit 54.

One of the electrodes E2 is disposed between the slit 54 and itsadjacent dummy slit E1. The electrode E2 is a wave-shaped structureextending along the longitudinal direction D2. The design of theelectrode E2 may refer to the conducting-wire portion W1. The electrodeE2 may be a portion of the transmission portion TX or theconducting-wire portions W1 of the transmission electrode 51. Theelectrode E2 may be a portion of the sensing electrode 52, the groundelectrode 53 or the dummy electrode.

FIG. 7 is a schematic view of the moiré zone Z2 of the touch layer 50 inaccordance with a third embodiment of the present disclosure. As shownin FIG. 7, the dummy slits E1 and the electrodes E2 are in a moiré zoneZ2. Each of the dummy slits E1 and its adjacent electrode E2 have adummy predetermined pitch P6 in a transverse direction D1. In otherwords, a dummy predetermined pitch P6 in a transverse direction D1 isdefined as a width of one of the dummy slits E1 plus a width of itsadjacent electrode E2. The moiré ratio is defined as (dummypredetermined pitch P6/pixel pitch P1) 100%. Therefore, in theembodiment, the dummy predetermined pitch P6 corresponding to theelectrode E2 corresponds to the predetermined pitch P4 defined byformula (1). In other words, the moiré ratio complies with formula (1).

The value of the longitudinal distance Ey/the transverse distance Ex ofthe electrode E2 is in a range from 0.33 to 3.05. In another embodiment,the value of the longitudinal distance Ey/the transverse distance Ex isin a range from 0.4 to 2.50, or from 0.45 to 2.15. When the value oflongitudinal distance Ey/transverse distance Ex is in the rangementioned above, the moiré effect in the moiré zone Z1 is decreased.Moreover, the arrangement ratio of the electrode E2 complies with theformula (2).

In conclusion, the pattern of the touch layer and the pixel areas aredesigned according to the formula of the present disclosure, the moiréeffect of the touch display is decreased, and the moiré pattern of theimages is decreased.

In some embodiments, the touch display 1 of the described disclosurescan be applied to various electronic apparatuses, such as touchapparatuses. FIG. 8 is a schematic view of a touch apparatus 100 inaccordance with the present disclosure. The touch apparatus 100comprises the touch display 1 configured to display images and providetouch functions. In some embodiments, the touch apparatus 100 is amobile phone, a tablet computer, a curved mobile phone, a curved tabletcomputer, or other suitable apparatuses. In some embodiments, the touchapparatus 100 is a flexible touch apparatus, or other suitableapparatuses.

While the invention has been described by way of example and in terms ofpreferred embodiment, it is to be understood that the invention is notlimited thereto. On the contrary, it is intended to cover variousmodifications and similar arrangements (as would be apparent to thoseskilled in the art). Therefore, the scope of the appended claims shouldbe accorded the broadest interpretation so as to encompass all suchmodifications and similar arrangements.

What is claimed is:
 1. A touch display, comprising: a display panel,having a plurality of pixel areas, wherein one of the pixel areas has apixel pitch in a first direction, and the display panel comprises: asubstrate; and a display medium layer, disposed over the substrate; atouch layer disposed over the substrate, the touch layer comprising; aplurality of slits, wherein the slits comprise a first slit and a secondslit adjacent to the first slit; and an electrode disposed between thefirst slit and the second slit, wherein the electrode comprises aplurality of first linear sections and a plurality of second linearsections alternately arranged in a second direction, the seconddirection is substantially perpendicular to the first direction, one ofthe first linear sections has an edge, and a first inflection point anda second inflection point are located at two ends of the edge, whereinan intersection point is defined as a crossing location of an extensionof the first inflection point in the first direction and an extension ofthe second inflection point in the second direction, a first distance isdefined as a distance between the first inflection point and theintersection point, and a second distance is defined as a distancebetween the second inflection point and the intersection point, whereina ratio of the second distance to the first distance is in a range from0.33 to 3.05.
 2. The touch display as claimed in claim 1, wherein thesubstrate is a transparent flexible substrate.
 3. The touch display asclaimed in claim 1, wherein the touch display is applied as a flexibletouch apparatus.
 4. The touch display as claimed in claim 1, wherein thedisplay medium layer is an organic light-emitting display layer.
 5. Thetouch display as claimed in claim 1, wherein the value of the seconddistance/the first distance is in a range from 0.4 to 2.50.
 6. The touchdisplay as claimed in claim 1, further comprising a color-filter layerdisposed over the substrate, wherein the touch layer is disposed betweenthe color-filter layer and the substrate, or the color-filter layer isdisposed between the touch layer and the substrate.
 7. A touch display,comprising: a display panel having a plurality of pixel areas, whereinone of the pixel areas has a pixel pitch in the transverse direction,and the display panel comprises: a substrate; and a display medium layerdisposed over the substrate; and a touch layer disposed over thesubstrate, and the touch layer comprising: a plurality of slitscomprising a first slit and a second slit adjacent to the first slit;and wherein a predetermined pitch is defined as a width of the electrodeplus a width of the first slit, a first moiré ratio is defined as (thepredetermined pitch/the pixel pitch)×100%, and the first moiré ratiocomplies with a first formula:25%+(50%×N)−A%≦the first moiré ratio≦25%+(50%×N)+A%, wherein the N is 0or a positive integer, and the A is an adjustment value in a range from0 to
 20. 8. The touch display as claimed in claim 7, wherein thesubstrate is a transparent flexible substrate.
 9. The touch display asclaimed in claim 7, wherein the touch display is applied as a flexibletouch apparatus.
 10. The touch display as claimed in claim 7, whereinthe display medium layer is an organic light-emitting display layer. 11.The touch display as claimed in claim 7, wherein the electrode is aportion of the transmission electrode, a portion of the sensingelectrode, a portion of the dummy electrode, or a portion of the groundelectrodes.
 12. The touch display as claimed in claim 7, wherein the Ais in a range from 5 to 15, or the N is in a range from 0 to
 8. 13. Thetouch display as claimed in claim 7, wherein the electrodes isdistributed in a first zone and a second zone adjacent to the firstzone, the first moiré ratio corresponds to the first zone, and theelectrode of the second zone has a second moiré ratio, wherein thesecond moiré ratio complies with a second formula:25%+(50%×(N+1))−A%≦the second moiré ratio≦25%+(50%×(N+1))+A%.
 14. Thetouch display as claimed in claim 7, wherein the electrode is awave-shaped structure, the electrode comprises a linear section, twoends of an edge of each of the linear sections have a first inflectionpoint and a second inflection point, an intersection point is disposedat a crossing location of an extension of the inflection point in thetransverse direction and an extension of the inflection point in thelongitudinal direction, wherein a transverse distance is defined as adistance between the first inflection point and the intersection point,and a longitudinal distance is defined as a distance between the secondinflection point and the intersection point.
 15. The touch display asclaimed in claim 14, wherein an arrangement ratio complies with a thirdformula: 25%+(50%×N)−B%≦the arrangement ratio 25%+(50%×N)+B%, whereinthe N is 0 or a positive integer, and the B is an adjustment value in arange from 0 to 20, wherein the arrangement ratio is defined as (thelongitudinal distance/the pixel pitch)×100%.
 16. The touch display asclaimed in claim 15, wherein B is in a range from 5 to 15, or the N isin a range from 0 to
 8. 17. The touch display as claimed in claim 14,wherein the value of the longitudinal distance/the transverse distanceis in a range from 0.33 to 3.05.
 18. The touch display as claimed inclaim 17, wherein the value of the longitudinal distance/the transversedistance is in a range from 0.4 to 2.50.
 19. The touch display asclaimed in claim 7, further comprising a color-filter layer disposedover the substrate, wherein the touch layer is disposed between thecolor-filter layer and the substrate, or the color-filter layer isdisposed between the touch layer and the substrate.